A cutting tool that has a leading or cutting surface that includes affixed thereto a plurality of irregular nine-faced polyhedrons or three-dimensional solid elements with nine faces, wherein each of the nine faces is a polygon and has a predetermined distance from each face to an opposing cutting edge and wherein the predetermined distance from each of the nine faces to its opposing cutting edge is equal for all of each of the nine faces, such that regardless of which of the nine faces is resting on a flat surface, the predetermined distance is the same.
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10. A down hole cutting tool comprising:
a longitudinal body having a leading surface;
a plurality of cutting elements affixed onto said leading surface; and
each of said cutting elements is an irregular polyhedron having a first face, a second face, a third face, a fourth face, a fifth face, a sixth face, a seventh face, an eighth face, and a ninth face;
each of said first through nine faces having a predetermined distance from each of said nine faces to an opposing cutting edge of each of said nine faces; and,
said predetermined distance is equal for each of said nine faces.
8. A cutting element, comprising:
an irregular polyhedron having a first face, a second face, a third face, a fourth face, a fifth face, a sixth face, a seventh face, an eighth face, and a ninth face;
said first face having five cutting edges;
said second face having four cutting edges;
said third face having five cutting edges;
said fourth face having five cutting edges;
said fifth face having five cutting edges;
said sixth face having four cutting edges;
said seventh face having four cutting edges;
said eighth face having four cutting edges;
said ninth face having four cutting edges;
each of said first through nine faces having a predetermined distance from each of said nine faces to an opposing cutting edge of each of said nine faces; and,
said predetermined distance is equal for each of said nine faces.
15. A method of cutting through material in a drilled hole such as an oil or gas well, the method comprising:
obtaining a cutting tool which has a front portion and a rear portion, said front portion having a leading surface;
affixing a plurality of nine-faced cutting elements onto said leading surface;
wherein each of said cutting elements is an irregular polyhedron having a first face, a second face, a third face, a fourth face, a fifth face, a sixth face, a seventh face, an eighth face, and a ninth face;
wherein each of said first through nine faces having a predetermined distance from each of said nine faces to an opposing cutting edge of each of said nine faces;
wherein said predetermined distance is equal for each of said nine faces;
inserting said cutting tool into a well or pipe;
rotating said cutting tool into said well or pipe;
wherein said cutting elements cut through material to be removed from said well or pipe.
1. A cutting element, comprising:
an irregular polyhedron having a first face, a second face, a third face, a fourth face, a fifth face, a sixth face, a seventh face, an eighth face, and a ninth face;
said first face having five cutting edges which form a pentagon comprising a first included angle α and a second included angle γ;
said second face having four cutting edges which form a trapezoid comprising a first included angle ε and a second included angle ζ;
said third face having five cutting edges which form a pentagon comprising a first included angle η and a second included angle θ;
said fourth face having five cutting edges which form an irregular pentagon comprising a first included angle ι, a second included angle κ and a third included angle λ;
said fifth face having five cutting edges which form an irregular pentagon comprising a first included angle ν, a second included angle μ and a third included angle ξ;
said sixth face having four cutting edges which form an irregular quadrilateral comprising a first included angle π, a second included angle ρ and a third included angle o;
said seventh face having four cutting edges which form an irregular quadrilateral comprising a first included angle υ, a second included angle τ and a third included angle σ;
said eighth face having four cutting edges which form an irregular quadrilateral comprising a first included angle φ, a second included angle χ;
said ninth face having four cutting edges which form an irregular quadrilateral comprising a first included angle ψ, a second included angle ω;
each of said first through nine faces having a predetermined distance from each of said nine faces to an opposing cutting edge of each of said nine faces; and,
said predetermined distance is equal for each of said nine faces.
3. A down hole cutting tool comprising:
a longitudinal body having a leading surface;
a plurality of cutting elements is affixed onto said leading surface;
each of said cutting elements is an irregular polyhedron having a first face, a second face, a third face, a fourth face, a fifth face, a sixth face, a seventh face, an eighth face, and a ninth face;
said first face having five cutting edges which form a pentagon comprising a first included angle α and a second included angle γ;
said second face having four cutting edges which form a trapezoid comprising a first included angle ε and a second included angle ζ;
said third face having five cutting edges which form a pentagon comprising a first included angle η and a second included angle θ;
said fourth face having five cutting edges which form an irregular pentagon comprising a first included angle ι, a second included angle κ and a third included angle λ;
said fifth face having five cutting edges which form an irregular pentagon comprising a first included angle ν, a second included angle μ and a third included angle ξ;
said sixth face having four cutting edges which form an irregular quadrilateral comprising a first included angle π, a second included angle ρ and a third included angle o;
said seventh face having four cutting edges which form an irregular quadrilateral comprising a first included angle υ, a second included angle τ and a third included angle σ;
said eighth face having four cutting edges which form an irregular quadrilateral comprising a first included angle φ, a second included angle χ;
said ninth face having four cutting edges which form an irregular quadrilateral comprising a first included angle ψ, a second included angle ω;
each of said first through nine faces having a predetermined distance from each of said nine faces to an opposing cutting edge of each of said nine faces; and,
said predetermined distance is equal for each of said nine faces.
4. The cutting tool of
5. The cutting tool of
6. The cutting tool of
7. The cutting tool of
11. The cutting tool of
12. The cutting tool of
13. The cutting tool of
14. The cutting tool of
16. The method of
17. The method of
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This application claims the benefit of U.S. provisional patent application Ser. No. 61/356,036, filed Jun. 17, 2010, the entirety of which is incorporated by reference herein.
The invention relates generally to downhole cutting tools, cutting inserts or elements used in such tools and methods of cutting, milling, or removing downhole items made of concrete, plastic, or other material, such as metal chips and casing strings in a well bore, including other types of passages through which fluid flows.
Downhole cutting tools and cutting elements are well known in the oil drilling industry. For example, U.S. Pat. No. 6,464,434 is directed to products and methods that are used in fishing tools, but it does not disclose structures or advantages that are provided by the structures disclosed herein. One of the drawbacks of known cutting tools and cutting elements is non-uniformity of the height of the elements when they are packed together or applied to a cutting tool surface, thus resulting in a relatively inefficient cutting tool because of the height variation.
The cutting elements and cutting tools described herein overcome drawbacks of known cutting elements, cutting tools, and methods of manufacture and use by providing cutting elements that can be applied randomly but are the same height any way they are oriented on the tool's surface. They result in significant advantages in cutting efficiency, in manufacturing and in use of tools that incorporate these cutting elements. Proper orientation during manufacturing is automatic and easily achieved, thus allowing for lower manufacturing costs, and wear on the tool during use downhole is more even, thus resulting in a longer useful life of the cutting tool.
The preferred embodiment of the cutting element described herein is generally comprised of an irregular polyhedron having nine faces and a plurality of cutting edges. These nine faces have predetermined sizes, shapes, edges and spatial relationships. Each of the nine faces has a predetermined distance from its face to a cutting edge opposite to that face. This predetermined distance from each face to its opposing cutting edge is equal for all of the nine faces, such that regardless of which of the nine faces rest on a flat surface, its opposing cutting edge is the same distance from that face.
These and other embodiments, features, aspects, and advantages of the invention will become better understood with regard to the following description, appended claims and accompanying drawings.
The foregoing aspects and the attendant advantages of the present invention will become more readily appreciated by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
Reference symbols or names are used in the figures to indicate certain components, aspects or features shown therein. Reference symbols common to more than one figure indicate like components, aspects or features shown therein.
With reference to
A cutting tool typically has a front portion and a rear portion. A plurality of cutting elements is preferably affixed onto a leading surface of the front portion of the cutting tool. During operation of the tool the elements cut through the unwanted material, or material which otherwise needs to be removed from a well bore or passage. The unwanted material to be cut through in such environments typically includes concrete casing strings, metal chips, drill pipe aggregates, plugs, and other trash. The terms typically used in the industry to describe this type of downhole tool are “junk mill,” “casing mill,” and “fishing tool.”
During normal use, cutting tools, which incorporate a plurality of the cutting elements described herein, are lowered or otherwise inserted into wells or pipes, and then rotated and forced downward with the front portion of the tool adapted to cut through unwanted material.
As shown in
As shown in
The cutting elements may be manufactured in heights greater than or less than 0.256 inch, for example, from a height of 0.150 inch or greater, as is needed based on the type of drilling or well boring application. As will be appreciated by those skilled in this field, the height of all the cutting elements will be equal for a given tool, but tools having different gauges may be made using batches of cutting elements, with the cutting element heights the same in each batch, but the heights variable from batch to batch.
Referring now to the top view of the cutting element as shown in
Referring to the top view of
Referring to the top view of
Referring to the top view of
Referring to the top view of
Referring to the top view of
Referring to the top view of
Referring to the top view of
Referring to the top view of
Referring to
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Referring to
As shown in
As noted above, the cutting elements may be manufactured with a predetermined distance from one face, to the opposing cutting edge, of greater than or less than 0.256 inch, so long as the heights of the cutting elements protruding from a cutting tool are equal for a given tool. However, cutting tools having different gauges may be made using batches of cutting elements, with the cutting element heights the same in each batch, but the heights variable from batch to batch.
As is apparent from the above description and figures, no matter how the cutting element lays on the tool, it always has a sharp cutting edge facing outward or up in order to provide a cutting edge which cuts through the unwanted material. Thus, any of the nine faces of the cutting element can be welded, bonded, or otherwise fastened to the front portion of a tool, but the distance from any of such nine faces to its respective opposing cutting edge, is the same. This is a significant advantage because it reduces the time it takes to apply the cutting elements, which enables the placement of a plurality of cutting elements in a random fashion. No careful alignment is necessary during the application process, whereas careful, time consuming and relatively expensive efforts are required when applying conventional cutting elements to a tool. In other words, traditionally engineered cutting products require careful alignment to ensure that the cutting elements are correctly positioned on the tool.
To further describe an advantage of the present cutting elements, as noted above, they are the same height any way they are oriented on the tool's front or leading surface. Therefore, achieving a particular gage height on the tool is automatic, and this step in the application process also reduces time needed to manufacture a fully dressed tool or as shown in
Additionally, the cutting elements described herein have included angles which are equal to or greater than 90 degrees. This geometry creates stronger edges than those elements having sharp, irregular edges. This geometry also results in less wear, thus allowing the product to maintain the gage height longer than traditional products.
The cutting elements are made with, preferably, cutting grade tungsten carbide, and are preferably attached to the tool with conventional welding, bonding, or brazing techniques. The cutting elements can be incorporated into the cutting tool, through welding, bonding, or brazing of its faces to the tool, with random placement of such elements and without regard to their alignment or uniformity. As shown in
Although specific embodiments of the invention have been described, various modifications, alterations, alternative constructions, and equivalents are also encompassed within the scope of the invention.
The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense. It will, however, be evident that additions, subtractions, deletions, and other modifications and changes may be made thereunto without departing from the broader spirit and scope of the invention as set forth in the claims.
Stroud, Donald Stuart, Stroud, Donald Gregory
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Jan 20 2011 | STROUD, DONALD STUART | AMERICAN NATIONAL CARBIDE, CO | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 025696 | /0325 | |
Jan 20 2011 | STROUD, DONALD GREGORY | AMERICAN NATIONAL CARBIDE, CO | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 025696 | /0325 | |
Jan 25 2011 | American National Carbide Co. | (assignment on the face of the patent) | / |
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